Electrical devices and methods for manufacturing same

ABSTRACT

An electrical device for soldering to a circuit board with a solder includes a capacitor, a lead frame including a solder dam, and a solder joint electrically coupling the capacitor to the lead frame. The solder dam includes one of a physical barrier to flow or an area of reduced wettability to the solder. The solder dam is between the solder joint and the circuit board. The solder dam is on one or both of a lead portion and main portion of the lead frame. In one embodiment, the first solder dam extends substantially the full width of the first lead portion. The solder dam may be a barrier and/or include a metal oxide. A method of manufacturing the device includes soldering a lead frame to a capacitor with a solder and modifying a surface on the lead frame to include a physical barrier and/or an area of reduced wettability.

CROSS REFERENCE

This application is a divisional of U.S. patent application Ser. No.14/251,988 filed Apr. 14, 2014 (pending), the disclosure of which isexpressly incorporated by reference herein in its entirety.

TECHNICAL FIELD

The present invention relates generally to electrical devices andmethods of manufacturing electrical devices, and more particularly, tocapacitor assemblies and methods of manufacturing those assemblies.

BACKGROUND

With reference to FIGS. 1 and 1A, multilayer capacitors or chips 10 arecommonly used for bypass, coupling, or energy storage applications inelectronic circuits. The capacitor 10 includes internal parallel plates12 and a dielectric body 14, typically made of a ceramic. Alternatingparallel plates 12 are connected by respective terminations 16, 18. Eachof the end terminations 16, 18 electrically couples to correspondingplates 12 and provides an external electrical connection to themultilayer capacitor 10. As shown, in some applications multiplecapacitors 10 may be stacked one on top of the other to create acombined capacitance equal to the sum of the capacitance of theindividual capacitors 10. Each of the capacitors 10 in the stack maythen be soldered at each end termination 16, 18 to a pair of opposinglead frames 20, 22 by corresponding solder joints 24, 26. The solderjoints 24, 26 electrically and mechanically couple the individualcapacitors 10 to the lead frames 20, 22 and form a stacked multilayercapacitor assembly 30.

The stacked multilayer capacitor assembly 30 may be subsequentlysoldered to a circuit board 32, often referred to as a printed circuitboard (PCB). As is known, circuit board 32 may include a plurality ofother electrical components (not shown), which may be electricallyconnected using conductive tracks or using other electrical connections(not shown). The circuit board 32 may include pads 36, 38 onto which themultilayer capacitor assembly 30 may be placed. Lead frames 20, 22 aresoldered to the pads 36, 38 forming solder fillets 40, 42 therebyelectrically connecting the stacked multilayer capacitor assembly 30 tothe other electrical components on the circuit board 32.

As is known, the lead frames 20, 22 are metal and are soldered betweenthe circuit board 32 and the multilayer capacitors 10 to providemechanical compliance between the multilayer capacitors 10 and thecircuit board 32. In this regard, the multilayer capacitors 10 oftenhave a thermal expansion coefficient that is typically less than thecircuit board 32. Consequently, during heating, the circuit board 32expands to a greater degree than the multilayer capacitor 10. In theabsence of compliance between the multilayer capacitor 10 and thecircuit board 32, the multilayer capacitor 10 and/or one or more of thesolder joints 24, 26 may crack or otherwise be destroyed or damaged.

Furthermore, the circuit board 32 may be more flexible than themultilayer capacitor 10. During flexing of the circuit board 32,significant mechanical stress may be applied to the multilayer capacitor10 in the absence of the lead frames 20, 22. Lead frames 20, 22 thusprovide compliance between the multilayer capacitor 10 and the circuitboard 32 and allow the circuit board 32 to flex or expand upon heatingwhile minimizing stress on the multilayer capacitors 10 and/or on thejoints 24, 26.

Even with lead frames to provide compliance, manufacturers of capacitorassemblies and PCB assemblers experience failures with stacked capacitorassemblies. In particular, multilayer capacitors may be inadvertentlyseparated from one or both of the lead frames during soldering of themultilayer capacitor to the PCB or during operation of the PCB.

While stacked capacitor assemblies have generally been successful,manufacturers strive to improve the stacked capacitor assemblies,particularly their durability and performance.

SUMMARY

The present invention overcomes the foregoing and other shortcomings anddrawbacks of electrical devices and methods for manufacturing thosedevices heretofore known for use in electronics and other environments.While the invention will be described in connection with certainembodiments, it will be understood that the invention is not limited tothese embodiments. On the contrary, the invention includes allalternatives, modifications and equivalents as may be included withinthe spirit and scope of the present invention.

According to one aspect of the present invention, an electrical devicefor soldering to a circuit board with a solder comprises a capacitor, afirst lead frame including a first solder dam, and a first solder jointelectrically coupling the capacitor to the first lead frame. The firstsolder dam includes one of a physical barrier to flow of the solder oran area of reduced wettability to the solder than a wettability of thesurfaces on the remainder of the first lead frame. When the electricaldevice is on the circuit board for soldering with the solder, the firstsolder dam is between the first solder joint and the circuit board.

In one embodiment, the electrical device further comprises a second leadframe including a second solder dam, and a second solder jointelectrically coupling the capacitor to the second lead frame. The secondsolder dam is between the second solder joint and the circuit board.

In one embodiment, each of the first solder dam and the second solderdam includes the physical barrier to flow of the solder and the area ofreduced wettability to the solder.

In one embodiment, the physical barrier to flow of the solder includesthe area of reduced wettability to the solder.

In one embodiment, the first lead frame includes a main portion and alead portion extending from the main portion. The first lead frame iscoupled to the capacitor proximate the main portion, and the leadportion or the main portion includes the solder dam.

In one embodiment, the first lead portion includes the first solder dam.

In one embodiment, the first solder dam extends substantially the fullwidth of the first lead portion.

In one embodiment, the first main portion includes the first solder dam.

In one embodiment, the first solder dam extends substantially the fullwidth of the main portion.

In one embodiment, the first lead portion extends a distance beyond thecapacitor so that when the electrical device is mounted to the circuitboard, the first lead portion couples the capacitor to the circuit boardand there is a gap between the capacitor and the circuit board. Thefirst solder dam is in the gap between the capacitor and the circuitboard.

In one embodiment, the first lead portion further includes a secondsolder dam on the surface of the first lead frame generally opposite thefirst solder dam.

In one embodiment, the first solder dam is directly opposite the secondsolder dam.

In one embodiment, the second solder dam is in the gap between thecapacitor and the circuit board.

In one embodiment, the first solder dam has an area of reducedwettability to the solder that includes a metal oxide. In oneembodiment, the metal of the metal oxide differs from the metal of theadjacent surfaces of the lead portion.

In one embodiment, the first solder dam includes a physical barrier inthe configuration of a recess.

In one embodiment, the recess is sand-blasted, scratched, chemicallyleached, or laser ablated into the surface of the lead portion.

In one embodiment, the first solder dam includes a non-solderable layer.

In one embodiment, the electrical device further includes a layer of thesolder on the first lead frame that is spaced apart from the firstsolder joint by the first solder dam.

In one embodiment, a circuit board includes the electronic device asdescribed herein.

According to one aspect of the present invention, a method ofmanufacturing an electrical device for soldering to a circuit board witha first solder comprises soldering a first lead frame to a multilayercapacitor with a second solder and modifying a surface portion on thefirst lead frame. When the electrical device is soldered to the circuitboard with the first solder, the surface portion is between the jointformed by the second solder and the circuit board. The surface portionincludes one of a physical barrier to the flow of the first solder or anarea of reduced wettability with the first solder as compared to thewettability of the first lead frame and the second lead frame with thefirst solder.

In one embodiment, the first lead frame includes an outer plating layerconfigured to facilitate soldering with the first solder, and modifyingthe surface portion includes removing the outer plating layer to form arecess and exposing a different underlying metal on the first leadframe.

In one embodiment, modifying the surface portion includes forming thearea of reduced wettability by oxidizing a metal in the first leadframe.

In one embodiment, the second solder has a higher melting point than thefirst solder.

In one embodiment, modifying the surface portion includes applying aphysical barrier in the form of a non-solderable coating to the firstlead frame.

In one embodiment, modifying the surface portion precedes soldering thefirst lead frame to the multilayer capacitor.

The advantages of the present invention shall be made apparent from theaccompanying drawings and the description thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate embodiments of the invention and,together with a general description of the invention given above, andthe detailed description given below, serve to explain the invention.

FIG. 1 is a side elevation view an electronic device soldered to acircuit board according to the prior art;

FIG. 1A is an enlarged cross-sectional view of the encircled area 1A ofFIG. 1;

FIG. 2A is an elevation view an electronic device having a failed solderjoint between a frame and a chip according to the prior art;

FIG. 2B is an elevation view of an electronic device having a failedsolder joint between a frame and a pad according to the prior art;

FIG. 3 is a side elevation view an electronic device having multiplefailed solder joints according to the prior art;

FIG. 4 is a perspective view of an electronic device according to oneembodiment of the invention;

FIG. 5 is a side elevation view of an electronic device after solderingto a circuit board according to one embodiment of the invention;

FIG. 6 is a side elevation view of an electronic device prior tosoldering to a circuit board according to one embodiment of theinvention;

FIG. 6A is an enlarged view of the encircled area 6A of FIG. 6 depictingone embodiment of a solder dam;

FIGS. 7A, 7B, and 7C are an enlarged views of the encircled area of FIG.6 depicting various embodiments of a solder dam according to the presentinvention;

FIG. 8 is a side elevation view of a lead frame according to oneembodiment of the invention;

FIG. 9 is a side elevation view of a lead frame according to oneembodiment of the invention;

FIG. 10 is a side elevation view of a lead frame according to oneembodiment of the invention; and

FIG. 11 is a side elevation view of a lead frame according to oneembodiment of the invention.

DETAILED DESCRIPTION

It is known that manufacturing an electrical device and attachment ofthat device to a circuit board may include a two stage solderingprocess. The solders in each of the two stages may be different. Withreference to FIG. 1, in one exemplary process using a capacitor assembly30 (described above), a high temperature solder is used to attach a pairof lead frames 20, 22 to one or more multilayer capacitors or chips 10,as is described above.

In the second stage, the stacked capacitor assembly 30 may be solderedto the circuit board 32. A low temperature solder may used to mount theassembly 30 to the circuit board 32. There are numerous processes bywhich a stacked capacitor assembly 30 may be soldered to the circuitboard pads 36, 38 with the low temperature solder. Exemplary solderingprocesses include, but are not limited to, manual soldering, wavesoldering, and reflow soldering, among others.

Generally, the high temperature solder of the first stage ischaracterized by higher liquidus temperature than the liquidustemperature of the low temperature solder of the second stage. Thus, thejoints 24, 26 formed during manufacturing of the capacitor assembly 30should not melt as a result of being inadvertently heated during thesubsequent lower-temperature mounting process. However, notwithstandingthe specific high-then-low soldering temperatures, the joints 24, 26formed of high temperature solder too often fail as a result of mountingthe capacitor assembly 30 to the circuit board 32 with the lowtemperature solder.

It is contemplated that the integrity of the joints 24, 26 may becompromised if the low temperature solder comes into contact with thehigh temperature solder during processing. Contact between the twosolders may occur during soldering of the assembly 30 to the circuitboard 32. Should there be contact between the high temperature solderand the low temperature solder, the assembly 30 and ultimately thecircuit board 32 to which the assembly 30 is attached may eventuallybecome inoperable.

Specifically, during a soldering process by which solder joints orfillets 40, 42 are formed between the lead frames 20, 22 and thecorresponding pad 36, 38, the low temperature solder that is to form oneor both of the fillets 40, 42 can flow from the region including thefillets 40, 42 into contact with one or more of the solder joints 24,26. This may be the result if excess supply of low temperature solder isused and/or if the assembly 30 is exposed for too long and/or at toohigh a temperature during the second stage of soldering. In this case,excess low temperature solder may accidently flow into one or more ofthe solder joints 24, 26.

It is contemplated that contact between the low temperature solder usedto form the fillets 40, 42 and the high temperature solder that is usedto form the joints 24, 26 can ultimately result in mechanical failure ofone or more of the solder joints 24, 26. In this regard, it is believedthat the low temperature solder may eventually alloy with the hightemperature solder at the temperatures observed during soldering, andeven at the temperatures observed during operation of the circuit board32. The resulting alloy may have a lower melting temperature than themelting temperature of even the low temperature solder alloy. Undercertain conditions, the solder alloy of the combination of the lowtemperature and high temperature solder may have a liquidus temperaturethat may be at or below the operating temperature of the joints 24, 26during use of the circuit board 32. As a consequence, operation of thecircuit board 32 may cause mechanical failure of the assembly 30 becauseone or more of the joints 24, 26 eventually melts or softens.

Specifically, during the process of manufacturing the stacked capacitorassembly 30, the solder used to form the joints 24, 26 may be a hightemperature solder. By way of example, and not limitation, the hightemperature solder may be a high lead alloy, such as a tin (Sn)-lead(Pb)-silver (Ag) alloy (e.g., 10Sn/88Pb/2Ag) and may be heated to atemperature of about 330° C. during reflow by which the lead frames 20,22 are soldered to the chips 10. The high temperature solder forms thejoints 24, 26 upon cooling.

Subsequent to the construction of the stacked capacitor assembly 30, asolder having a lower reflow temperature than the reflow temperature ofthe high temperature solder may be utilized to attach the assembly 30 tothe circuit board 32 and to form the fillets 40, 42. By way of example,and not limitation, the low temperature solder may be a high tin solder,such as a tin (Sn)-silver (Ag) alloy (e.g., 96Sn/4Ag) or a tin (Sn)-lead(Pb) alloy (e.g., 63Sn/37Pb) and may be heated to a temperature ofbetween about 220° C. and about 260° C. during reflow by which thestacked capacitor assembly 30 is soldered to the circuit board 32.

Contact between the low temperature solder and the high temperaturesolder may result in a low melting temperature alloy. By way of example,according to a phase diagram for Sn—Pb, changing the relative amounts ofPb and Sn in the high temperature solder may produce a new alloy that atleast partially melts at a lower temperature. For example, an eutecticis formed between Sn and Pb at approximately 61.9 wt. % Pb and 38.1 wt.% Sn, the composition of which melts at a temperature of about 183° C.Thus, depending upon the composition of the new alloy, it may melt at alower temperature than either of the high temperature solder or the lowtemperature solder. This may cause problems with the joints 24, 26during the mounting procedure and afterwards if heated to at or near themelting temperature of the new alloy.

During use of the circuit board 32, the joints 24, 26 may fail becausethe new alloy may have a liquidus temperature at or near the temperatureof the joints 24, 26 during operation of the circuit board 32. Thus, itis believed that contact between the high temperature solder alloy ofthe joints 24, 26 and the low temperature solder may have a catastrophiceffect on the joints 24, 26 and thus shorten the life span of theassembly 30. While specific high temperature and low temperature solderalloys are described herein, it will be appreciated that the alloyingproblem described above is not limited to combinations of theseparticular high temperature solders and low temperature solders, asother solder alloys having differing liquidus temperatures when broughtinto contact with one another may produce similar catastrophic effectsduring operation of the circuit board.

Exemplary catastrophic failures of the assembly 30 are depictedschematically in FIGS. 2A, 2B, and 3. As a result of contact between thelower temperature solder alloy and the solder joints 24, 26, the joints24, 26 may gradually melt or otherwise fail at undesirably lowtemperatures. As is shown in FIG. 2A, the lowermost chip 10 may slumponto the circuit board 32 when contact between the low temperaturesolder and the joint 26 of the lowermost chip 10 causes the joint 26 tomelt when the circuit board 32 is in use. The lowermost chip 10, in theabsence of the joint 26 and under the influence of gravity, may bepulled onto the circuit board 32 and may thus disconnect from the leadframe 22 or form a high-resistance connection to the lead frame whichdegrades the operation of the overall assembly.

In FIG. 2B, the solder may migrate or wick up a lead frame 22 and starvethe joint between the lead frame 22 and the pad 38. As a result, afillet 42 (FIG. 2A) does not form and the frame 22 may only be weaklysecured to the pad 38. Ultimately, the assembly 30 may disconnect fromthe circuit board 32 or the frame 22 may only periodically contact thepad 38 resulting in an unreliable or high resistance electricalconnection with the pad 38.

Another possible catastrophic failure is shown in FIG. 3 in which theassembly 30 falls apart. As shown, the lead frame 22 may tilt away fromthe chips 10. One result may be that each lead frame 20, 22 losescontact with each chip 10 or forms only high resistance connections toeach chip. That is, each solder joint 24, 26 on each chip 10 fails.

In view of the alloying of the different solders and associatedproblems, as identified in the preceding paragraphs, embodiments of thepresent invention include a solder dam configured to keep a solder(e.g., a high temperature solder) utilized to assemble an electricaldevice from coming into contact with a solder of different composition(e.g., a low temperature solder) utilized to assemble the electricaldevice with a substrate, such as a circuit board.

To that and other ends, the solder dam may act as a barrier that stopsflow or resists flow of liquid solder or diffusion on selected surfacesof an electronic device, such as, a stacked multilayer capacitorassembly. In this regard and as is described in detail below,embodiments of the present invention may include a stacked multilayercapacitor assembly having one or more solder dams. Solder dams accordingto embodiments of the present invention may include an area over whichthe liquid solder is prohibited or at least inhibited from flowing. Anexemplary solder dam may include a region of reduced wettability to thesolder and/or one or more physical barriers that stop or reduce the flowof the liquid solder, each of which is described below.

As is known in the art, wettability describes the relationship between asolid and a liquid in contact with the solid and depends upon theinterfacial energies between the liquid, a vapor, and the solid. If thesolid-liquid interfacial energy is high, the liquid will not “wet” thesurface and tends to form a ball-shape having a small interfacial areawith the surface. In contrast, if the solid-vapor interfacial energy ishigh (or the solid-liquid interfacial energy is low), the liquid willtend to spontaneously spread out on the surface. Generally, the degreeto which a liquid wets a solid is quantified by a contact angle, whichis an angle measured between the solid surface and the liquid surface atthe interface between the solid, the liquid, and the vapor. A measuredcontact angle of 0° indicates that the liquid spontaneously flows acrossthe solid surface. As the contact angle increases from 0°, the liquid'stendency to spread along a solid's surface is reduced. For measuredcontact angles of greater than 0° to 90°, the liquid is described as“wetting” the surface, and for measured contact angles greater than 90°,the liquid is described as “non-wetting.” Thus, embodiments of theelectrical device according to the present invention may include asolder dam having a surface that is nonwettable to the liquid solderadjacent a surface that is wettable or include a surface that hasreduced wettability to the liquid solder adjacent a surface that is morewettable.

In addition or as an alternative to relative differences in interfacialenergies to affect the wettability, the solder dam may include aphysical barrier to the flow of liquid solder. Physical barriers mayinclude a feature over which the liquid solder does not readily flow. Byway of example, these features may include a ridge that extends abovethe surrounding surface or a recess that reside below the surroundingsurface of the lead frame. Physical barriers may completely block flowof liquid solder or may slow the flow of liquid solder.

As a result of the solder dam, and by way of example, it is contemplatedthat during a surface mount operation the solder utilized to connect theelectrical device to the substrate is prevented or at least inhibited bythe area of reduced wettability and/or physical barrier to a degreesufficient to prevent the solder from flowing into contact with anothersolder already present on the electrical device. No low temperaturealloy is thus formed. According to embodiments of the invention, whetherincluding a solder dam having an area of reduced wettability and/orhaving features over which solder is inhibited from flowing, the solderdam may not completely stop solder flow. Nevertheless, the solder dameffectively prevents contact between solders of different compositionsduring a mounting operation of the electrical device to a substrate. Forexample, the solder dam effectively prevents a low temperature solderused for surface mounting of an electrical device from coming intocontact with a high temperature solder used in the assembly of theelectrical device. Accordingly, the solder dam is located on theelectrical device between the two solders.

In particular, with reference now to FIG. 4, in which like features areindicated by like numerals throughout the figures, in one embodiment ofthe invention, a stacked multilayer capacitor assembly 44 includes oneor more multilayer capacitors or chips 10 as described above anddepicted in FIG. 1. The stacked multilayer capacitor assembly 44includes opposing lead frames 46, 48. The chips 10 are coupled to thelead frames 46, 48 by respective solder joints 24, 26. The solder joints24, 26 may each be formed of a high temperature solder, such as, a highlead alloy described above. The joints 24, 26 may electrically couplethe chips 10 at their respective end terminations 16, 18 to thecorresponding lead frame 46, 48. Each lead frame 46, 48 is metallic andmay be about 250 μm thick.

Specifically, as is known in the art, lead frames may be constructedfrom a flat sheet of metal that may be stamped, electroformed, or photoetched to the desired configuration. By way of example only, the metalof each of the lead frames 46, 48 may be a nickel-iron alloy (e.g.,FeNi42 referred to as Alloy 42 or Kovar®, a trademark of CRS Holdings,Inc.), copper, a copper alloy, a phosphorous-copper-tin alloy, silver,or a beryllium-copper alloy, to name a few. The lead frames 46, 48 mayalso include one or more plating layers over a core of theabove-identified metals. Embodiments of the present invention are not,however, limited to the material of the lead frames 46, 48 or anycoatings that are plated or otherwise coated onto a core metal to formthe lead frames 46, 48.

As shown in FIG. 4, in one embodiment, each lead frame 46, 48 mayinclude one or more solder dams 58, 60, 62, 64. Exemplary solder dams58, 60, 62, and 64 may be a result of adding material, of removingmaterial, or otherwise processing the surface of the lead frame 46, 48as described below. These processes may form a physical barrier, such asa ridge on the surface of the lead frame 46, 48 or a recess in thesurface of the lead frame 46, 48, each described in detail below.Further, the ridge or recess may include a surface of reducewettability. However, it will be appreciated that the physical barrierto liquid solder flow may be utilized alone, that is, without a surfaceof reduced wettability.

The location of the solder dams 58, 60, 62, and 64 may vary on each ofthe interior surface (i.e. between the opposing lead frames 46, 48) andthe exterior surface (i.e., the outwardly-facing surfaces of the leadframes 46, 48). However, the solder dams 58, 60, 62, and 64 are locatedbetween the joints 24, 26 and the location onto which a second solder isused to couple the lead frames 46, 48 to a circuit board.

In this regard, each lead frame 46, 48 may include a main portion 50, 52and one or more lead portions 54, 56. The solder dams 58, 60, 62, 64 maybe located on the main portions 50, 52 and/or each lead portion 54, 56,as described below. While the figures depict lead frames 46, 48 havingthe solder dam on each one of the interior surface and the exteriorsurface, embodiments of the present invention are not limited to havingsolder dams on each surface. It will be appreciated that the solder dams58, 60, 62, 64 may be used in any combination on any one or more ofinterior and exterior surfaces of the lead frames 46, 48.

In one embodiment, the solder dam 58, 60, 62, 64, reduces the flow rateof the liquid solder upward along the surface of the lead frame 46, 48.The reduction in flow rate may be sufficient to eliminate orsignificantly reduce the quantity of contact between the liquid solderand the joints 24, 26 during the time a circuit board is exposed to theliquid solder. In particular, it is noted that the liquid solder maycross the solder dam 58, 60, 62, 64 during the soldering operation yetthe solder dam 58, 60, 62, 64 slows the flow rate by an amountsufficient to prevent contact with the joints 24, 26 during thesoldering process. By way of example only, the solder dam 58, 60, 62, 64may prevent contact between the joints 24, 26 with the liquid solder fora period of up to 120 seconds, for a period of about 90 seconds or less,for a period of about 45 seconds or less, for a period of 25 seconds orless, or for a period of from about 20 to about 25 seconds duringsoldering of the assembly to the circuit board 32.

The stacked multilayer capacitor assembly 44 may be exposed to multiplemounting procedures in the event that an initial mounting procedurefails to solder one or more components onto the circuit board 32. Evenin view of the reduction in the flow rate of liquid solder past thesolder dam 58, 60, 62, 64, it will be appreciated that, given a longenough time at a high enough temperature and/or a sufficient amount ofsolder, the solder may flow across the solder dam 58, 60, 62, 64.Nevertheless, in mounting operations in which one or more of the time,temperature, and the amount of solder is poorly controlled, embodimentsof the present invention may eliminate or significantly reduce thefrequency of contact between the liquid solder and the joints 24, 26.Embodiments of the present invention may therefore eliminate or reducecontact between the liquid solder and the joints 24, 26 for at least onemounting process. Further, the solder dam 58, 60, 62, 64 may limit flowover multiple mounting operations and may reduce or eliminate contactbetween the liquid solder and the joints 24, 26 during each procedure.By way of example, the solder dam 58, 60, 62, 64 may limit flow for atleast two mounting procedures and by way of additional example thesolder dam 58, 60, 62, 64 may limit flow for at least three mountingprocedures.

To that end, the solder dams 58, 60, 62, and 64 may reduce the flow ofliquid solder. Exemplary solder dams 58, 60, 62, and 64 may be theresult of surface modification of the lead frame 46, 48 and includeeither of material added to the surface of the lead frame 46, 48 ormaterial removed from the surface of the lead frame 46, 48.Specifically, for example, the solder dams 58, 60, 62, 64 may be in theform of a ridge projecting outwardly relative to the surrounding surfaceof the respective lead frame 46, 48 (shown best in FIGS. 6 and 6A).Alternatively, for example, the solder dams 58, 60, 62, and 64 may be inthe configuration of a recess in the lead frame 46, 48 (shown best inFIGS. 7A-7C) that may be formed generally by removing material. Each ofthese configurations is described in more detail below. The recess andridge slows the flow of molten solder upward along the surface of thelead frames 46, 48 and prevents contact between the liquid solder andthe joints 24, 26 during a mounting process.

Each of the ridge or recess may include an area of reduced wettabilitythat, in combination, reduces the flow of the liquid solder relative tothe surface of the lead frames 46, 48. However, it will be appreciatedthat either the area of reduced wettability or the physical barrieralone may be sufficient to reduce the flow of solder and prevent contactbetween a liquid solder and an existing solder joint. Embodiments of thepresent invention may not include both the physical barrier and an areaof reduced wettability.

As described above and with regard to wettability, unlike the surfacesof the lead frame 46, 48, the solder dam 58, 60, 62, 64 may include asurface area that may be non-wetting (forms a contact angle of 90° ormore) to the solder. Alternatively, the molten solder may form a contactangle of less than 90° with a surface area of the solder dam 58, 60, 62,64. That is, the liquid solder may wet the solder dam 58, 60, 62, 64 butonly to a lesser degree than the surface of the lead frames 46, 48. Thecontact angle of the molten solder in contact with the solder dam 58,60, 62, 64 may be greater than the contact angle formed between themolten solder and the surface of lead frames 46, 48.

By way of example and not limitation, the solder may form a contactangle with the solder dam 58, 60, 62, 64 that is about 10% greater thanthe contact angle formed between the molten solder and the surface ofthe lead frame 46, 48 and by way of additional example, the moltensolder may form a contact angle with the solder dam 58, 60, 62, 64 thatis about 20% greater than the contact angle formed between the moltensolder and the surface of the lead frame 46, 48. This difference inwettability slows the flow of molten solder upward along the surface ofthe lead frames 46, 48 relative to a lead frame lacking the area ofreduced wettability.

Now with further detail as to the location of the solder dams 58, 60,62, 64, as is described above and with reference to FIGS. 4 and 5, inone embodiment of the invention, the solder dams 58, 60, 62, 64 may belocated between the joints 24, 26 and the circuit board 32 when thestacked multilayer capacitor assembly 44 is placed onto the circuitboard 32 for mounting thereon. More specifically, in one embodiment, themain portion 50, 52 includes one or more solder dams 58, 60, 62, 64. Thelocation of the solder dams 58 and/or 60 is not, however, limited toplacement in or on the main portion 50, 52 (as shown), as otherlocations between the solder joints 24, 26 and the circuit board 32 arepossible which will be in the pathway of any liquid solder that may wickupward along the lead portions 54, 56 toward the solder joints 24, 26.

In this regard and with continued reference to FIGS. 4 and 5, in oneembodiment, each lead portion 54, 56 may include the corresponding foot66, 68 that ultimately forms the contact area that will touch thecircuit board 32, and specifically contact with the pads 36, 38 (FIG.5). The feet 66, 68 are spaced apart and are at the other end of thelead frame 46, 48 from the main portion 50, 52. The feet 66, 68 may besoldered to the pads 36, 38 with a low temperature solder during, forexample, a wave soldering process.

In the embodiment shown in FIG. 4, collectively, the feet 66, 68 of eachlead frame 46, 48 are formed with a retainer 70, 72. The retainers 70,72 may ensure that each of the lead portions 54, 56 remains straight(i.e., does not get bent) during handling of the stacked multilayercapacitor assembly 44. The retainer 70, 72 may eventually be removed bycutting each lead frame 46, 48 along exemplary line 74, 76 prior tosoldering the stacked multilayer capacitor assembly 44 to a circuitboard.

By separating the lead portions 54, 56 from the retainer 70, 72, eachlead portion 54, 56 may then be separately secured to the circuit board32. It will be appreciated that the feet 66, 68 may be bent prior tobeing soldered to the pads 36, 38, respectively. In this regard, leadportions 54, 56 may be referred to as “J” style (shown in FIG. 5), “L”style, or “Z” style leads as are known in the art. Other styles mayinclude “N” style or “P” style though embodiments of the presentinvention are not limited to any particular style of lead as otherconfigurations are possible.

In view of the above and with reference to FIG. 5, solder dams 58, 60,62, 64 may be positioned on the lead frames 46, 48 between the joints24, 26 and the feet 66, 68. Placement of the solder dams 58, 60, 62, 64may vary between the interior surfaces and the exterior surfaces of thelead frames 46, 48 as well.

As is shown in FIG. 5, the solder dams 58, 60, 62, 64 are positionedbetween the feet 66, 68 and the joints 24, 26. Solder that wicks up thelead portions 54, 56 (as indicated by arrows 78) on the inside andoutside of the lead frames 46, 48 during formation of the fillets 40, 42is prevented or at least inhibited from contacting the joints 24, 26during mounting of the stacked multilayer capacitor assembly 44 to thecircuit board 32 or during another process. In particular, the interiorsolder dams 62, 64 may be positioned on the interior of thecorresponding lead frames 46, 48 between the lowermost chip 10 and thecircuit board 32. Because the distance between the lowermost chip 10 andthe circuit board 32 is limited, by way of example, this gap may be0.045 inches or less. The interior solder dams 62, 64 may therefore bepositioned on the corresponding lead portion 54, 56. The exterior solderdams 58, 60 may be positioned on the lead portion 54, 56 or the mainportion 50, 52. Due to the relative space limitations, the solder dams58, 60, 62, 64 between the inside and the outside of the lead portions54, 56 may be different both in dimension and in shape.

Specifically, and with reference to FIGS. 6 and 6A, due to the limitedspace on the interior surface of the lead portions 54, 56, the solderdams 62, 64 positioned on the interior surface may have a smalleroverall dimension in the direction of potential solder flow (indicatedby arrows 78 in FIG. 5). The solder dams 58, 60 on the exterior of thelead frames 46, 48 may not be so limited in dimension or in location.Generally, the solder dams 58, 60 may be larger than the correspondingsolder dams 62, 64 on the interior surfaces of the lead frames 46, 48.Although not shown, large areas of the exterior surfaces of the leadframes 46, 48 may include solder dams 58, 60. It may be possible, forexample, for one or both of the solder dams 62, 64 to encompass theentire main portion 50, 52 with or without covering portions of the leadportions 54, 56.

Furthermore, the solder dams 58, 60 on the exterior of the lead frames46, 48 may be positioned directly across from the interior solder dams62, 64, the exterior solder dams 58, 60 may be positioned closer to thefeet 66, 68 than the solder dams 62, 64, or directly across from thelowermost joints 24, 26, or the relative placement of the solder dams58, 60 may be a combination of these locations. The interior andexterior solder dams 58, 60 and 62, 64, respectively, may also differ inconfiguration as is described in detail below.

In addition to the advantages described above during the mountingprocess of the assembly 44 to the circuit board 32, embodiments of thepresent invention inhibit flow of a preexisting low temperature solder(not shown) on the feet 66, 68 from flowing toward the chips 10 duringformation of the joints 24, 26. In this regard, one method ofmanufacturing the stacked capacitor assembly 44 is to solder the leadframes 46, 48 having a pre-coating of low temperature solder on the feet66, 68 to the chips 10. A pre-coating of solder on the lead frames 46,48 may be provided by the lead frame manufacturer to simplify thesubsequent mounting process of the stacked capacitor assembly 44 to thecircuit board 32. During this type of manufacturing of the stackedcapacitor assembly 44 with precoated lead frames 46, 48, the feet 66, 68are typically oriented to project above the chips 10. This orientationmay be referred to as “dead bug” style.

In this dead bug style, a high temperature solder may be used to formthe joints 24, 26. As is described above, to solder the chips 10 to thelead frames 46, 48 with a high temperature solder requires reflowtemperatures greater than the liquidus temperature of the preexistinglow temperature solder. At these higher temperatures, the preexistinglow temperature solder on the feet 66, 68 may be heated to above itsliquidus temperature and thus the preexisting low temperature solder maymelt and flow down toward the joints 24, 26 during their formation. Aswith the alloying problems described in conjunction with FIGS. 2 and 3,manufacturing of the stacked capacitor assembly 44 in dead bug stylewith a preexisting low temperature solder is similarly problematic dueto a lower temperature alloy formation.

Embodiments of the present invention are advantageous because the solderdams 58, 60, 62, 64 may prevent the preexisting low temperature solderfrom flowing down the lead frame 46, 48 and into contact with the joints24, 26 as they are being formed with the high temperature solder. Thus,embodiments of the present invention may include stacked capacitorassemblies 44 having a low temperature solder covering at least aportion of the lead portions 54, 56, particularly, but not limited to,the feet 66, 68.

As described above, each solder dam 58, 60, 62, 64 may be the result ofmodifying a surface portion of the lead frame 46, 48. Modification mayinclude removing material from the surface of the lead frames 46, 48 oradding material to the frames 46, 48. In this regard, in one embodiment,solder dams 58, 60, 62, 64 may each be a recess (material removedrelative to the lead frames 46, 48) or a ridge (material added to thelead frames 46, 48) on the interior and/or exterior surfaces of the leadframes 46, 48.

In this regard and with reference to FIGS. 5, 6, and 6A, one or more thesolder dams 58, 60, 62, 64 may be a ridge of material added to thesurface of the lead frames 46, 48. Each of the solder dams 58, 60, 62,64 shown in FIG. 6 is a ridge. The shape of the ridge slows liquidsolder flow. For example, the ridge may be defined at least in part byat least one sharp corner 84 over which liquid solder may not readilyflow. The sharp corners of the rectangular cross-sectional configurationthat project outwardly relative to the surrounding surface may inhibitmovement of the liquid solder over the ridge. While a rectangularcross-sectional configuration is shown in FIGS. 6 and 6A, embodiments ofthe ridge are not limited to a rectangular cross-sectional configurationas there are other cross-section configurations having sharp corners orother features that slow the flow of liquid solder.

In one exemplary process, the ridge may be formed by plating or sprayingthe surface of the lead frame 46, 48 so as to add material to thesurface of the lead frame 46, 48. The lead frame 46, 48 may be sprayedprior to soldering the chips 10 to the lead frames 46, 48. Spraying orplating may therefore be performed by the lead frame manufacturer.Alternatively, the lead frame 46, 48 may be sprayed or plated followingmanufacturing of the stacked capacitor assembly 44. In this case, themanufacturer of the stacked capacitor assembly may coat one or both ofthe lead frames 46, 48 prior to assembly or subsequent to soldering thechips 10 to the lead frames 46, 48. The material of the ridge may be apolymer-containing material, such as, an epoxy, an acrylic, or paralene(also known as Parylene) (unsubstituted poly(para-xylylene), e.g.,Parylene N, and substituted poly(para-xylylene), e.g., Parylene C andParylene D), and polytetrafluoroethylene (PTFE), to name a few. In oneembodiment, the ridge may project at least about 100 microinches (about0.0001 inch) outwardly from the surrounding surfaces of the lead frame46, 48. In another embodiment, the ridge may project from about 100microinches (about 0.0001 inch) to about 1 mil (about 0.001 inch)outwardly from the surface of the lead frame 46, 48. In yet anotherembodiment, the ridge may project from about 1 μm (about 3.94×10⁻⁵ inch)to about 10 μm (about 0.000394 inch) outwardly from the surface of thelead frame 46, 48. (In view of these exemplary dimensions, it will beappreciated that the figures may not be drawn to scale.) In oneembodiment, the ridge includes at least one surface area ofnon-wettability or of reduced wettability to liquid solder flow.

With reference now to FIGS. 5 and 7A-7C, in one embodiment, at least oneof the solder dams 58, 60, 62, 64 is a recess in the surface of at leastone of the lead frames 46 and 48. With reference specifically to FIG.7A, the recess 60 may be a depression or slot in the surface of the leadframe 46. In one embodiment, the recess may be at least about 100microinches (about 0.0001 inch) deep. In another embodiment, the recessmay be from about 100 microinches (about 0.0001 inch) deep to about 1mil (about 0.001 inch) deep. In yet another embodiment, the recess maybe from about 1 μm (about 3.94×10⁻⁵ inch) deep to about 10 μm (about0.000394 inch) deep. (In view of these exemplary depths, it will beappreciated that the figures may not be drawn to scale.) The shape ofthe recess slows liquid solder flow. For example, the recess may bedefined at least in part by at least one sharp corner 84 over whichliquid solder may not readily flow. The sharp corners of the rectangularcross-sectional configuration that are positioned inwardly relative tothe surrounding surface may inhibit movement of the liquid solder overthe recess. While a rectangular cross-sectional configuration is shownin FIG. 7, embodiments of the recess are not limited to a rectangularcross-sectional configuration as there are other cross-sectionconfigurations having sharp corners or other features that slow the flowof liquid solder.

In one embodiment, one surface of the recess 60 may include an area ofnon-wettability or an area of reduced wettability compared to thesurface of the lead frames 46, 48. It will be appreciated that therecess with or without an area of reduced wettability to the liquidsolder, may act as a physical boundary to liquid solder flow. There maybe many processes by which the recess may be formed.

The recess may be formed by a machining process in which material isremoved from the lead frames 46, 48. In one exemplary process, therecess may be formed by sandblasting the surface of the lead frame 48 soas to remove metal from the surface of the lead frame 48. The lead frame48 may be sandblasted prior to soldering the chips 10 to the lead frames46, 48. Sandblasting may therefore be performed by the lead framemanufacturer.

Alternatively, the lead frame 48 may be sand blasted followingmanufacturing of the stacked capacitor assembly 44. In this case, themanufacturer of the stacked capacitor assembly may sand blast the leadframe 48 prior to assembly or subsequent to soldering the chips 10 tothe lead frames 46, 48.

In one embodiment and with reference to FIG. 7A, sandblasting may beused to remove a plated layer 80 from a core material 82 therebyexposing the core material 82 within the recess. The plated layer 80 maybe about 100 microinches thick. So, sandblasting may just remove theplated layer 80 with minimal removal of the core material 82. It will beappreciated however that sandblasting may remove a significantproportion of the core material 82 as well, which may result in depthsin excess of 100 microinches.

In one embodiment, to control the location of the solder dam formed bysandblasting, a masking material may be used to protect areas of thelead frames 46, 48. The masking material may be adhesive tape, whichcould be peeled off after sandblasting is complete, or an organicpolymer, which may be subsequently removed with a solvent or by othermeans. The recess may be formed by other methods.

By way of additional example, many lead frames are manufactured by anetching process in which the metallic sheet is etched into the shape ofthe lead frame using a laser or chemicals, such as, an acid bath. Thisetching process may be used to form the recess as a separate additionaletching process or in conjunction with forming the lead frame itself.Specifically, the etching process may be utilized to remove all or aportion of the plated layer 80 from the core material 82.

In another exemplary process, the lead frame 46, 48 may be scraped orscratched to remove an outer layer of the lead frame 46, 48. This mayresult in a roughened topology as is shown in FIG. 7C.

As yet another example of forming the recess, during manufacturing ofthe lead frame, an organic coating (not shown), such as, asilicone-based material, a polyimide-based material, or a paralenematerial may be used to mask an area of a core material 82 where therecess is to be formed while leaving a remaining area of the corematerial 82 exposed. The core material 82 having the masked area maythen be plated with one or more of silver (Ag), copper (Cu), nickel(Ni), gold (Au), tin (Sn), or tin (Sn)-lead (Pb) to form the platedlayer 80 over the exposed areas of the core 82. Selection of thematerial of the plated layer 80 may depend upon the specific electricaland thermal conductivity requirements of the lead frame. During plating,the plating material may not coat the organic coating but may coat theremainder of the core material 82. Removing the organic coating mayleave a recess, as is depicted in FIGS. 7A and 7B. Thus, rather thanremoving a preexisting plated layer 80 to form the recess, the recess isformed by masking the core material 82, adding plating material aroundthe mask, and then removing the mask.

A recess formed in any of the above-described manners may leave the corematerial 82 exposed. Where the core material 82 is a metal, once thatmetal is exposed to the ambient environment under the necessaryconditions, the metal may oxidize. In this regard, oxidation of the corematerial 82 may occur in a separate dedicated process by which the leadframe 46, 48 is exposed to an atmosphere to intentionally oxidize themetal of the core material 82. In one exemplary oxidation process, thelead frame 46, 48 may be placed into an oven with air and heated for apredetermined amount of time to oxidize the core material 82.Alternatively, or in combination with a separate process, the exposedcore material 82 may spontaneously oxidize during a solder reflow stepin which the chips 10 are soldered together with the lead frames 46, 48.Many metals are known to form a tough oxide layer that is not easilyremoved including, but not limited to, iron (Fe), iron alloys, nickel(Ni), and nickel alloys, to name a few. It is known that copper (Cu) andsilver (Ag) may also form oxide surface layers that are more easilyremoved than an iron oxide layer. Nevertheless, these oxides may also beused to form one or more of the solder dams 58, 60, 62, 64 according toembodiments of the invention. Oxidation of the exposed metal may resultin a layer of metal oxide that may be only a few angstroms (less thanabout 10 Å) thick, though thicker metal oxide layers are possible andmay depend on the constituent metal elements in the recess.

In any event, the oxidized metal may form an area of reduced wettabilityto the liquid solder of the solder dam 58, 60, 62, 64. That is, in oneembodiment, during mounting the stacked capacitor assembly 44 to thecircuit board 32, the liquid solder used to form fillets 40, 42 may notreach the joints 24, 26 because the flow rate of the liquid solder isreduced sufficiently by at least the presence of the metal oxide in therecess so that there is insufficient time for the solder to flow acrossthe solder dam 58, 60, 62, 64 to reach the joints 24, 26 during themounting process.

According to any one of these processes, and with reference to FIGS. 7Band 7C, multiple recesses may be formed adjacent one another. By way ofexample only, as shown in FIG. 7B, two recesses may be formed into thesurface of the lead frames 46, 48. It will be appreciated thatembodiments of the present invention are not limited to having a singlerecess or two recesses, as multiple recesses may be formed along thesurfaces of one or both of the lead frames 46, 48.

In this regard, as shown in FIG. 7C, the recess may include a contouredsurface. This may include an intentionally roughened surface having aroughness that exceeds the roughness of the surface of the lead frame48. By way of example, the surface roughness in the recess may exceedthat by at least 10%. The intentionally roughened surface may includemultiple, overlapping recesses that collectively form a single macrorecess as depicted in FIG. 7C. Not being bound to any theory, it iscontemplated that the higher surface area within the recess due to thegreater roughness and/or the multiple peaks and valleys within thesurface roughness may reduce the flow of liquid solder across therecess.

Any of the above-described solder dams 58, 60, 62, 64 (e.g., the recess,the ridge, or the surface having a reduced wettability) may be in theform of a stripe 86, as is shown in FIG. 8. The stripe may be a uniform,linear stripe formed along the surface of the lead frame 46, 48 havingany one of the cross-sectional configurations shown in FIG. 6, 6A or7A-7C. As shown in FIG. 8, the solder dam 58, 60, 62, 64 extendssubstantially the full width of the lead frame 46, 48, that is, from oneedge to the opposing edge of the main portion 50, 52. While not shown,anyone single one of the solder dams 58, 60, 62, 64 may extend aroundeach opposing edge of the lead frame 46, 48. Embodiments of the presentinvention are not limited to a linear stripe 86 shown in FIG. 8. By wayof example, other configurations may include a nonlinear stripe 88, asshown in FIG. 9. The nonlinear stripe 88 may be discontinuous but mayextend across each of the separate leads of the lead portion 54, 56 andbe in the form of an arc or have a circular configuration.

Other stripe configurations are shown in FIGS. 10 and 11, in which thestripe 90 extends across each of the leads of the lead portion 54, 56,but is more linearly formed.

While the present invention has been illustrated by a description ofvarious embodiments and while these embodiments have been described insome detail, it is not the intention of the inventors to restrict or inany way limit the scope of the appended claims to such detail.Additional advantages and modifications will readily appear to thoseskilled in the art. The various features of the invention may be usedalone or in any combination depending on the needs and preferences ofthe user.

What is claimed is:
 1. A method of manufacturing an electrical devicefor soldering to a circuit board with a first solder, the methodcomprising: soldering a first lead frame to a multilayer capacitor witha second solder; and modifying a surface portion on the first leadframe, wherein when the electrical device is soldered to the circuitboard with the first solder, the surface portion is between a jointformed by the second solder with the circuit board, wherein the surfaceportion includes one of a physical barrier to a flow of the first solderor an area of reduced wettability with the first solder as compared tothe wettability of the first lead frame and the second lead frame withthe first solder.
 2. The method of manufacturing of claim 1, wherein thefirst lead frame includes an outer plating layer configured tofacilitate soldering with the first solder, and wherein modifying thesurface portion includes removing the outer plating layer to form arecess.
 3. The method of manufacturing of claim 2, wherein removingincludes exposing a different underlying metal on the first lead frame.4. The method of manufacturing of claim 1, wherein modifying the surfaceportion includes forming the area of reduced wettability by oxidizing ametal in the first lead frame.
 5. The method of manufacturing of claim1, wherein the second solder has a higher melting point than the firstsolder.
 6. The method of manufacturing of claim 1, wherein modifying thesurface portion includes applying the physical barrier to the first leadframe.
 7. The method of manufacturing of claim 6, wherein the physicalbarrier is a non-solderable coating.
 8. The method of manufacturing ofclaim 1, wherein modifying the surface portion precedes soldering thefirst lead frame to the multilayer capacitor.
 9. The method ofmanufacturing of claim 1, further comprising: soldering a second leadframe to the multilayer capacitor with the second solder and modifying asurface portion on the second lead frame.
 10. The method ofmanufacturing of claim 1, wherein the first lead frame includes a mainportion and a lead portion extending from the main portion and beingconfigured to couple the multilayer capacitor to the circuit board, eachof the main portion and the lead portion having a width, and whereinmodifying the surface portion includes modifying substantially the fullwidth of the main portion.
 11. The method of manufacturing of claim 1,wherein the first lead frame includes a main portion and a lead portionextending from the main portion and being configured to couple themultilayer capacitor to the circuit board, each of the main portion andthe lead portion having a width, and wherein modifying the surfaceportion includes modifying substantially the full width of the leadportion.
 12. The method of manufacturing of claim 1, wherein modifyingthe modifying the surface portion on the first lead frame includesmodifying a second surface portion of the first lead frame on a surfaceopposite to the surface portion.
 13. The method of manufacturing ofclaim 1, wherein modifying the surface portion includes sand blasting atleast a portion of the first lead frame.
 14. The method of manufacturingof claim 1, wherein modifying the surface portion includes chemicallyleaching at least a portion of the first lead frame.
 15. The method ofmanufacturing of claim 1, wherein modifying the surface portion includeslaser ablating at least a portion of the first lead frame.